Experimental study of passive scalar mixing in swirling jet flows

Despite its importance in various industrial applications there is still a lack of experimental studies on the dynamic and thermal field of swirling jets in the near-field region. The present study is an attempt to close this lack and provide new insights on the effect of rotation on the turbulent m...

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Main Author: Örlü, Ramis
Format: Others
Language:English
Published: KTH, Mekanik 2006
Subjects:
Online Access:http://urn.kb.se/resolve?urn=urn:nbn:se:kth:diva-4142
http://nbn-resolving.de/urn:isbn:91-7178-381-4
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spelling ndltd-UPSALLA1-oai-DiVA.org-kth-41422013-01-08T13:10:39ZExperimental study of passive scalar mixing in swirling jet flowsengÖrlü, RamisKTH, MekanikStockholm : KTH2006Fluid mechanicsswirling jetturbulencepassive scalarmixinghot-wire anemometrycold-wireFluid mechanicsStrömningsmekanikDespite its importance in various industrial applications there is still a lack of experimental studies on the dynamic and thermal field of swirling jets in the near-field region. The present study is an attempt to close this lack and provide new insights on the effect of rotation on the turbulent mixing of a passive scalar, on turbulence (joint) statistics as well as the turbulence structure. Swirl is known to increase the spreading of free turbulent jets and hence to entrain more ambient fluid. Contrary to previous experiments, which leave traces of the swirl generating method especially in the near-field, the swirl was imparted by discharging a slightly heated air flow from an axially rotating and thermally insulated pipe (6 m long, diameter 60 mm). This gives well-defined axisymmetric streamwise and azimuthal velocity distributions as well as a well-defined temperature profile at the jet outlet. The experiments were performed at a Reynolds number of 24000 and a swirl number (ratio between the angular velocity of the pipe wall and the bulk velocity in the pipe) of 0.5. By means of a specially designed combined X-wire and cold-wire probe it was possible to simultaneously acquire the instantaneous axial and azimuthal velocity components as well as the temperature and compensate the former against temperature variations. The comparison of the swirling and non-swirling cases clearly indicates a modification of the turbulence structure to that effect that the swirling jet spreads and mixes faster than its non-swirling counterpart. It is also shown that the streamwise velocity and temperature fluctuations are highly correlated and that the addition of swirl drastically increases the streamwise passive scalar flux in the near field. QC 20101124Licentiate thesis, monographinfo:eu-repo/semantics/masterThesistexthttp://urn.kb.se/resolve?urn=urn:nbn:se:kth:diva-4142urn:isbn:91-7178-381-4Trita-MEK, 0348-467X ; 2006:11application/pdfinfo:eu-repo/semantics/openAccess
collection NDLTD
language English
format Others
sources NDLTD
topic Fluid mechanics
swirling jet
turbulence
passive scalar
mixing
hot-wire anemometry
cold-wire
Fluid mechanics
Strömningsmekanik
spellingShingle Fluid mechanics
swirling jet
turbulence
passive scalar
mixing
hot-wire anemometry
cold-wire
Fluid mechanics
Strömningsmekanik
Örlü, Ramis
Experimental study of passive scalar mixing in swirling jet flows
description Despite its importance in various industrial applications there is still a lack of experimental studies on the dynamic and thermal field of swirling jets in the near-field region. The present study is an attempt to close this lack and provide new insights on the effect of rotation on the turbulent mixing of a passive scalar, on turbulence (joint) statistics as well as the turbulence structure. Swirl is known to increase the spreading of free turbulent jets and hence to entrain more ambient fluid. Contrary to previous experiments, which leave traces of the swirl generating method especially in the near-field, the swirl was imparted by discharging a slightly heated air flow from an axially rotating and thermally insulated pipe (6 m long, diameter 60 mm). This gives well-defined axisymmetric streamwise and azimuthal velocity distributions as well as a well-defined temperature profile at the jet outlet. The experiments were performed at a Reynolds number of 24000 and a swirl number (ratio between the angular velocity of the pipe wall and the bulk velocity in the pipe) of 0.5. By means of a specially designed combined X-wire and cold-wire probe it was possible to simultaneously acquire the instantaneous axial and azimuthal velocity components as well as the temperature and compensate the former against temperature variations. The comparison of the swirling and non-swirling cases clearly indicates a modification of the turbulence structure to that effect that the swirling jet spreads and mixes faster than its non-swirling counterpart. It is also shown that the streamwise velocity and temperature fluctuations are highly correlated and that the addition of swirl drastically increases the streamwise passive scalar flux in the near field. === QC 20101124
author Örlü, Ramis
author_facet Örlü, Ramis
author_sort Örlü, Ramis
title Experimental study of passive scalar mixing in swirling jet flows
title_short Experimental study of passive scalar mixing in swirling jet flows
title_full Experimental study of passive scalar mixing in swirling jet flows
title_fullStr Experimental study of passive scalar mixing in swirling jet flows
title_full_unstemmed Experimental study of passive scalar mixing in swirling jet flows
title_sort experimental study of passive scalar mixing in swirling jet flows
publisher KTH, Mekanik
publishDate 2006
url http://urn.kb.se/resolve?urn=urn:nbn:se:kth:diva-4142
http://nbn-resolving.de/urn:isbn:91-7178-381-4
work_keys_str_mv AT orluramis experimentalstudyofpassivescalarmixinginswirlingjetflows
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